int bitstream_read_bytes(struct input_bitstream *stream, size_t n, void *dest)
{
/* Precondition: The bitstream is 16-byte aligned. */
- wimlib_assert(stream->bitsleft % 16 == 0);
+ wimlib_assert2(stream->bitsleft % 16 == 0);
u8 *p = dest;
return 0;
}
-/* Aligns the bitstream on a 16-bit boundary.
- *
- * Note: M$'s idea of "alignment" means that for some reason, a 16-bit word
- * should be skipped over if the buffer happens to already be aligned on such a
- * boundary. This only applies for realigning the stream after the blocktype
- * and length fields of an uncompressed block, however; it does not apply when
- * realigning the stream after the end of the uncompressed block.
- */
-int align_input_bitstream(struct input_bitstream *stream,
- bool skip_word_if_aligned)
-{
- int ret;
- if (stream->bitsleft % 16 != 0) {
- bitstream_remove_bits(stream, stream->bitsleft % 16);
- } else if (skip_word_if_aligned) {
- if (stream->bitsleft == 0) {
- ret = bitstream_ensure_bits(stream, 16);
- if (ret != 0) {
- ERROR("Unexpected end of input when "
- "aligning bitstream");
- return ret;
- }
- }
- bitstream_remove_bits(stream, 16);
- }
- return 0;
-}
-
/*
* Builds a fast huffman decoding table from a canonical huffman code lengths
* table. Based on code written by David Tritscher.
/* Reads a Huffman-encoded symbol when it is known there are less than
* MAX_CODE_LEN bits remaining in the bitstream. */
-static int read_huffsym_near_end_of_input(struct input_bitstream *istream,
- const u16 decode_table[],
- const u8 lens[],
- unsigned num_syms,
- unsigned table_bits,
- unsigned *n)
+int read_huffsym_near_end_of_input(struct input_bitstream *istream,
+ const u16 decode_table[],
+ const u8 lens[],
+ unsigned num_syms,
+ unsigned table_bits,
+ unsigned *n)
{
unsigned bitsleft = istream->bitsleft;
unsigned key_size;
*n = sym;
return 0;
}
-
-/*
- * Reads a Huffman-encoded symbol from a bitstream.
- *
- * This function may be called hundreds of millions of times when extracting a
- * large WIM file. I'm not sure it could be made much faster that it is,
- * especially since there isn't enough time to make a big table that allows
- * decoding multiple symbols per lookup. But if extracting files to a hard
- * disk, the IO will be the bottleneck anyway.
- *
- * @buf: The input buffer from which the symbol will be read.
- * @decode_table: The fast Huffman decoding table for the Huffman tree.
- * @lengths: The table that gives the length of the code for each
- * symbol.
- * @num_symbols: The number of symbols in the Huffman code.
- * @table_bits: Huffman codes this length or less can be looked up
- * directory in the decode_table, as the
- * decode_table contains 2**table_bits entries.
- */
-int read_huffsym(struct input_bitstream *stream,
- const u16 decode_table[],
- const u8 lengths[],
- unsigned num_symbols,
- unsigned table_bits,
- unsigned *n,
- unsigned max_codeword_len)
-{
- /* In the most common case, there are at least max_codeword_len bits
- * remaining in the stream. */
- if (bitstream_ensure_bits(stream, max_codeword_len) == 0) {
-
- /* Use the next table_bits of the input as an index into the
- * decode_table. */
- u16 key_bits = bitstream_peek_bits(stream, table_bits);
-
- u16 sym = decode_table[key_bits];
-
- /* If the entry in the decode table is not a valid symbol, it is
- * the offset of the root of its Huffman subtree. */
- if (sym >= num_symbols) {
- bitstream_remove_bits(stream, table_bits);
- do {
- key_bits = sym + bitstream_peek_bits(stream, 1);
- bitstream_remove_bits(stream, 1);
-
- wimlib_assert(key_bits < num_symbols * 2 +
- (1 << table_bits));
- } while ((sym = decode_table[key_bits]) >= num_symbols);
- } else {
- wimlib_assert(lengths[sym] <= table_bits);
- bitstream_remove_bits(stream, lengths[sym]);
- }
- *n = sym;
- return 0;
- } else {
- /* Otherwise, we must be careful to use only the bits that are
- * actually remaining. */
- return read_huffsym_near_end_of_input(stream, decode_table,
- lengths, num_symbols,
- table_bits, n);
- }
-}